A metadynamics study of water oxidation reactions at (001)-WO3/liquid-water interface

IF 11.5 Q1 CHEMISTRY, PHYSICAL

Chem Catalysis Pub Date : 2024-08-29 DOI:10.1016/j.checat.2024.101085

Rangsiman Ketkaew, Fabrizio Creazzo, Kevin Sivula, Sandra Luber

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Metadynamics simulation suggests that the oxygen–oxygen (<span><span style=\"\"></span><span data-mathml='<math xmlns=\"http://www.w3.org/1998/Math/MathML\"><mrow is=\"true\"><mi mathvariant=\"normal\" is=\"true\">O</mi><mo is=\"true\">&#x2212;</mo><mi mathvariant=\"normal\" is=\"true\">O</mi></mrow></math>' role=\"presentation\" style=\"font-size: 90%; display: inline-block; position: relative;\" tabindex=\"0\"><svg aria-hidden=\"true\" focusable=\"false\" height=\"2.202ex\" role=\"img\" style=\"vertical-align: -0.351ex;\" viewbox=\"0 -796.9 2779.9 947.9\" width=\"6.457ex\" xmlns:xlink=\"http://www.w3.org/1999/xlink\"><g fill=\"currentColor\" stroke=\"currentColor\" stroke-width=\"0\" transform=\"matrix(1 0 0 -1 0 0)\"><g is=\"true\"><g is=\"true\"><use xlink:href=\"#MJMAIN-4F\"></use></g><g is=\"true\" transform=\"translate(1000,0)\"><use xlink:href=\"#MJMAIN-2212\"></use></g><g is=\"true\" transform=\"translate(2001,0)\"><use xlink:href=\"#MJMAIN-4F\"></use></g></g></g></svg><span role=\"presentation\"><math xmlns=\"http://www.w3.org/1998/Math/MathML\"><mrow is=\"true\"><mi is=\"true\" mathvariant=\"normal\">O</mi><mo is=\"true\">−</mo><mi is=\"true\" mathvariant=\"normal\">O</mi></mrow></math></span></span><script type=\"math/mml\"><math><mrow is=\"true\"><mi mathvariant=\"normal\" is=\"true\">O</mi><mo is=\"true\">−</mo><mi mathvariant=\"normal\" is=\"true\">O</mi></mrow></math></script></span>) bond formation induced by oxidative reactant species and oxygen atoms on the surface is the rate-determining step. Not only bond distances but also extended social permutation invariant (xSPRINT) coordinates and deep autoencoder neural network (DAENN) are used as collective variables (CVs) in metadynamics calculations to characterize the FESs of the studied reactions. The FES calculations using xSPRINT and DAENN CVs show that the formation of <span><span style=\"\"></span><span data-mathml='<math xmlns=\"http://www.w3.org/1998/Math/MathML\"><mrow is=\"true\"><msup is=\"true\"><mtext is=\"true\">OH</mtext><mo is=\"true\">&#x2022;</mo></msup></mrow></math>' role=\"presentation\" style=\"font-size: 90%; display: inline-block; position: relative;\" tabindex=\"0\"><svg aria-hidden=\"true\" focusable=\"false\" height=\"2.202ex\" role=\"img\" style=\"vertical-align: -0.235ex;\" viewbox=\"0 -846.5 1982.9 947.9\" width=\"4.605ex\" xmlns:xlink=\"http://www.w3.org/1999/xlink\"><g fill=\"currentColor\" stroke=\"currentColor\" stroke-width=\"0\" transform=\"matrix(1 0 0 -1 0 0)\"><g is=\"true\"><g is=\"true\"><g is=\"true\"><use xlink:href=\"#MJMAIN-4F\"></use><use x=\"778\" xlink:href=\"#MJMAIN-48\" y=\"0\"></use></g><g is=\"true\" transform=\"translate(1529,432)\"><use transform=\"scale(0.707)\" xlink:href=\"#MJMAIN-2219\"></use></g></g></g></g></svg><span role=\"presentation\"><math xmlns=\"http://www.w3.org/1998/Math/MathML\"><mrow is=\"true\"><msup is=\"true\"><mtext is=\"true\">OH</mtext><mo is=\"true\">•</mo></msup></mrow></math></span></span><script type=\"math/mml\"><math><mrow is=\"true\"><msup is=\"true\"><mtext is=\"true\">OH</mtext><mo is=\"true\">•</mo></msup></mrow></math></script></span> and <span><span style=\"\"></span><span data-mathml='<math xmlns=\"http://www.w3.org/1998/Math/MathML\"><mrow is=\"true\"><msub is=\"true\"><mi mathvariant=\"normal\" is=\"true\">H</mi><mn is=\"true\">2</mn></msub><msub is=\"true\"><mi mathvariant=\"normal\" is=\"true\">O</mi><mn is=\"true\">2</mn></msub></mrow></math>' role=\"presentation\" style=\"font-size: 90%; display: inline-block; position: relative;\" tabindex=\"0\"><svg aria-hidden=\"true\" focusable=\"false\" height=\"2.432ex\" role=\"img\" style=\"vertical-align: -0.582ex;\" viewbox=\"0 -796.9 2436.8 1047.3\" width=\"5.66ex\" xmlns:xlink=\"http://www.w3.org/1999/xlink\"><g fill=\"currentColor\" stroke=\"currentColor\" stroke-width=\"0\" transform=\"matrix(1 0 0 -1 0 0)\"><g is=\"true\"><g is=\"true\"><g is=\"true\"><use xlink:href=\"#MJMAIN-48\"></use></g><g is=\"true\" transform=\"translate(750,-150)\"><use transform=\"scale(0.707)\" xlink:href=\"#MJMAIN-32\"></use></g></g><g is=\"true\" transform=\"translate(1204,0)\"><g is=\"true\"><use xlink:href=\"#MJMAIN-4F\"></use></g><g is=\"true\" transform=\"translate(778,-150)\"><use transform=\"scale(0.707)\" xlink:href=\"#MJMAIN-32\"></use></g></g></g></g></svg><span role=\"presentation\"><math xmlns=\"http://www.w3.org/1998/Math/MathML\"><mrow is=\"true\"><msub is=\"true\"><mi is=\"true\" mathvariant=\"normal\">H</mi><mn is=\"true\">2</mn></msub><msub is=\"true\"><mi is=\"true\" mathvariant=\"normal\">O</mi><mn is=\"true\">2</mn></msub></mrow></math></span></span><script type=\"math/mml\"><math><mrow is=\"true\"><msub is=\"true\"><mi mathvariant=\"normal\" is=\"true\">H</mi><mn is=\"true\">2</mn></msub><msub is=\"true\"><mi mathvariant=\"normal\" is=\"true\">O</mi><mn is=\"true\">2</mn></msub></mrow></math></script></span>, respectively, is more energetically (in terms of the free-energy barrier) favorable than the formation of oxygen gas at the <span><span style=\"\"></span><span data-mathml='<math xmlns=\"http://www.w3.org/1998/Math/MathML\"><mrow is=\"true\"><msub is=\"true\"><mtext is=\"true\">WO</mtext><mn is=\"true\">3</mn></msub></mrow></math>' role=\"presentation\" style=\"font-size: 90%; display: inline-block; position: relative;\" tabindex=\"0\"><svg aria-hidden=\"true\" focusable=\"false\" height=\"2.432ex\" role=\"img\" style=\"vertical-align: -0.582ex;\" viewbox=\"0 -796.9 2260.9 1047.3\" width=\"5.251ex\" xmlns:xlink=\"http://www.w3.org/1999/xlink\"><g fill=\"currentColor\" stroke=\"currentColor\" stroke-width=\"0\" transform=\"matrix(1 0 0 -1 0 0)\"><g is=\"true\"><g is=\"true\"><g is=\"true\"><use xlink:href=\"#MJMAIN-57\"></use><use x=\"1028\" xlink:href=\"#MJMAIN-4F\" y=\"0\"></use></g><g is=\"true\" transform=\"translate(1807,-150)\"><use transform=\"scale(0.707)\" xlink:href=\"#MJMAIN-33\"></use></g></g></g></g></svg><span role=\"presentation\"><math xmlns=\"http://www.w3.org/1998/Math/MathML\"><mrow is=\"true\"><msub is=\"true\"><mtext is=\"true\">WO</mtext><mn is=\"true\">3</mn></msub></mrow></math></span></span><script type=\"math/mml\"><math><mrow is=\"true\"><msub is=\"true\"><mtext is=\"true\">WO</mtext><mn is=\"true\">3</mn></msub></mrow></math></script></span> surface/liquid-water interface. It is found that the <span><span style=\"\"></span><span data-mathml='<math xmlns=\"http://www.w3.org/1998/Math/MathML\"><mrow is=\"true\"><mi mathvariant=\"normal\" is=\"true\">O</mi><mo is=\"true\">&#x2212;</mo><mi mathvariant=\"normal\" is=\"true\">O</mi></mrow></math>' role=\"presentation\" style=\"font-size: 90%; display: inline-block; position: relative;\" tabindex=\"0\"><svg aria-hidden=\"true\" focusable=\"false\" height=\"2.202ex\" role=\"img\" style=\"vertical-align: -0.351ex;\" viewbox=\"0 -796.9 2779.9 947.9\" width=\"6.457ex\" xmlns:xlink=\"http://www.w3.org/1999/xlink\"><g fill=\"currentColor\" stroke=\"currentColor\" stroke-width=\"0\" transform=\"matrix(1 0 0 -1 0 0)\"><g is=\"true\"><g is=\"true\"><use xlink:href=\"#MJMAIN-4F\"></use></g><g is=\"true\" transform=\"translate(1000,0)\"><use xlink:href=\"#MJMAIN-2212\"></use></g><g is=\"true\" transform=\"translate(2001,0)\"><use xlink:href=\"#MJMAIN-4F\"></use></g></g></g></svg><span role=\"presentation\"><math xmlns=\"http://www.w3.org/1998/Math/MathML\"><mrow is=\"true\"><mi is=\"true\" mathvariant=\"normal\">O</mi><mo is=\"true\">−</mo><mi is=\"true\" mathvariant=\"normal\">O</mi></mrow></math></span></span><script type=\"math/mml\"><math><mrow is=\"true\"><mi mathvariant=\"normal\" is=\"true\">O</mi><mo is=\"true\">−</mo><mi mathvariant=\"normal\" is=\"true\">O</mi></mrow></math></script></span> bond formation is sluggish because of the stable electronic state of the surface and that the formation of <span><span style=\"\"></span><span data-mathml='<math xmlns=\"http://www.w3.org/1998/Math/MathML\"><mrow is=\"true\"><msup is=\"true\"><mtext is=\"true\">OH</mtext><mo is=\"true\">&#x2022;</mo></msup></mrow></math>' role=\"presentation\" style=\"font-size: 90%; display: inline-block; position: relative;\" tabindex=\"0\"><svg aria-hidden=\"true\" focusable=\"false\" height=\"2.202ex\" role=\"img\" style=\"vertical-align: -0.235ex;\" viewbox=\"0 -846.5 1982.9 947.9\" width=\"4.605ex\" xmlns:xlink=\"http://www.w3.org/1999/xlink\"><g fill=\"currentColor\" stroke=\"currentColor\" stroke-width=\"0\" transform=\"matrix(1 0 0 -1 0 0)\"><g is=\"true\"><g is=\"true\"><g is=\"true\"><use xlink:href=\"#MJMAIN-4F\"></use><use x=\"778\" xlink:href=\"#MJMAIN-48\" y=\"0\"></use></g><g is=\"true\" transform=\"translate(1529,432)\"><use transform=\"scale(0.707)\" xlink:href=\"#MJMAIN-2219\"></use></g></g></g></g></svg><span role=\"presentation\"><math xmlns=\"http://www.w3.org/1998/Math/MathML\"><mrow is=\"true\"><msup is=\"true\"><mtext is=\"true\">OH</mtext><mo is=\"true\">•</mo></msup></mrow></math></span></span><script type=\"math/mml\"><math><mrow is=\"true\"><msup is=\"true\"><mtext is=\"true\">OH</mtext><mo is=\"true\">•</mo></msup></mrow></math></script></span> and <span><span style=\"\"></span><span data-mathml='<math xmlns=\"http://www.w3.org/1998/Math/MathML\"><mrow is=\"true\"><msub is=\"true\"><mi mathvariant=\"normal\" is=\"true\">H</mi><mn is=\"true\">2</mn></msub><msub is=\"true\"><mi mathvariant=\"normal\" is=\"true\">O</mi><mn is=\"true\">2</mn></msub></mrow></math>' role=\"presentation\" style=\"font-size: 90%; 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引用次数: 0

Abstract

A metadynamics method was used to calculate the free energy surfaces (FESs) of the oxygen evolution reaction (OER). Metadynamics simulation suggests that the oxygen–oxygen ( $O - O$ $O - O$ ) bond formation induced by oxidative reactant species and oxygen atoms on the surface is the rate-determining step. Not only bond distances but also extended social permutation invariant (xSPRINT) coordinates and deep autoencoder neural network (DAENN) are used as collective variables (CVs) in metadynamics calculations to characterize the FESs of the studied reactions. The FES calculations using xSPRINT and DAENN CVs show that the formation of ${OH}^{•}$ ${OH}^{•}$ and $H_{2} O_{2}$ $H_{2} O_{2}$ , respectively, is more energetically (in terms of the free-energy barrier) favorable than the formation of oxygen gas at the ${WO}_{3}$ ${WO}_{3}$ surface/liquid-water interface. It is found that the $O - O$ $O - O$ bond formation is sluggish because of the stable electronic state of the surface and that the formation of ${OH}^{•}$ ${OH}^{•}$ and $H_{2} O_{2}$ $H_{2} O_{2}$ occurs through an energy barrierless process.

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(001)-WO3/ 水-液界面水氧化反应的元动力学研究

采用元动力学方法计算了氧进化反应（OER）的自由能面（FES）。元动力学模拟表明，氧化反应物和表面氧原子诱发的氧-氧（O-OO-O）键形成是决定速率的步骤。在元动力学计算中，不仅使用了键距，还使用了扩展社会包覆不变性（xSPRINT）坐标和深度自动编码神经网络（DAENN）作为集合变量（CV），以描述所研究反应的 FES 特性。使用 xSPRINT 和 DAENN CVs 进行的 FES 计算表明，在 WO3WO3 表面/液-水界面上，OH-OH- 和 H2O2H2O2 的形成在能量（自由能垒）上分别比氧气的形成更有利。研究发现，由于表面的电子状态稳定，O-OO-O 键的形成比较缓慢，而 OH-OH- 和 H2O2H2O2 的形成是通过无能障过程进行的。

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来源期刊

Chem Catalysis

CiteScore

10.50

自引率

6.40%

发文量

期刊介绍： Chem Catalysis is a monthly journal that publishes innovative research on fundamental and applied catalysis, providing a platform for researchers across chemistry, chemical engineering, and related fields. It serves as a premier resource for scientists and engineers in academia and industry, covering heterogeneous, homogeneous, and biocatalysis. Emphasizing transformative methods and technologies, the journal aims to advance understanding, introduce novel catalysts, and connect fundamental insights to real-world applications for societal benefit.